JP6822443B2 - Communication devices, information processing systems, information processing methods and computer programs - Google Patents

Description

The present invention relates to a communication device mounted / connected to a power storage element and / or a power supply-related device, an information processing system using the communication device, an information processing method, and a computer program.

Energy storage devices are widely used in uninterruptible power supplies, DC or AC power supplies included in regulated power supplies, and the like. The use of power storage elements in large-scale systems that store the generated power is expanding. In the present specification, the power storage element refers to all elements that perform power storage. The smallest unit of a power storage element is called a power storage cell.

Maintenance activities of power storage elements are important in uninterruptible power supplies, regulated power supplies, or power generation systems. A technology that enables a user or a maintenance person of a power storage element to remotely acquire information on the state of charge (SOC: State Of Charge) or life prediction information of the power storage element included in these systems via a server device. Has been proposed.

Patent Document 1 proposes a system in which an operator remotely visually recognizes the predicted value of the deterioration rate of a power storage element via a server device and a network. It is known that the storage cell deteriorates by repeating charging and discharging. In Patent Document 1, the predicted value of the deterioration rate is calculated remotely, that is, the life is predicted by using the data of the usage conditions and the deterioration rate.

Japanese Unexamined Patent Publication No. 2015-121520

In parallel with the penetration of IoT (Internet of Things) into society, expectations are rising for the realization of remote monitoring of power storage elements and power supply-related devices and the realization of highly convenient value-added services. Remote monitoring requires highly accurate state estimation and life prediction. Therefore, the measured values such as voltage, current, and temperature in the power storage element, or the state of the power supply-related device are acquired at a predetermined sampling timing. The higher the sampling frequency, the more accurately the state of the power storage element or the power supply-related device can be grasped, but the amount of information increases and the calculation load and communication load become heavy. It is desirable to sample at an appropriate frequency according to the state of the power storage element and the power supply related device.

The present invention provides a communication device, an information processing system, an information processing method, and a computer program capable of maintaining the accuracy of state determination of a power storage element or a power supply-related device while considering a calculation load and a communication load. With the goal.

The communication device is connected to the power storage element or the power supply-related device, and is based on a set timing of information including the state of the first communication unit that communicates with the power storage element or the power supply-related device and the state of the power storage element or the power supply-related device. The first communication unit communicates with the first device to acquire information acquired by the acquisition unit, a change reception unit that accepts and changes the timing change, and the acquisition unit at the timing after the change. It includes a transmission unit that transmits to the device.

It is a figure which shows the outline of the remote monitoring system. It is a block diagram which shows the structure of a remote monitoring system. It is a figure which shows an example of the hierarchical structure of a power storage module group, and the connection form of a communication device. It is a figure which shows another example of the hierarchical structure of a power storage module group, and the connection form of a communication device. It is a flowchart which shows an example of the instruction acceptance procedure in a communication device. It is a figure which shows the screen example presented by a server apparatus. It is a figure which shows the screen example presented by a server apparatus. It is a figure which shows the screen example presented by a communication device. It is a figure which shows the screen example presented by a communication device. It is a flowchart which shows an example of the processing procedure in a server apparatus.

The communication device is connected to the power storage element or the power supply-related device, and is based on a set timing of information including the state of the first communication unit that communicates with the power storage element or the power supply-related device and the state of the power storage element or the power supply-related device. The first communication unit communicates with the first device to acquire information acquired by the acquisition unit, a change reception unit that accepts and changes the timing change, and the acquisition unit at the timing after the change. It includes a transmission unit that transmits to the device.

With the above configuration, it is possible for the communication device connected / mounted to the power storage element or the power supply-related device to accept a change in the timing of acquiring the set information. You can remotely increase or decrease the timing or return to the default settings.

The change receiving unit transmits screen information for displaying the screen for accepting the timing change to the second device including the display unit by the second communication unit, and is displayed by the display unit included in the second device. You may accept the change of the timing on the screen. With this configuration, it is possible to remotely accept changes (for example, manual input) on the screen.

The change receiving unit may receive the instruction for changing the timing transmitted from the first device by the second communication unit. With this configuration, it is possible to change the timing (remote control) according to an instruction transmitted remotely.

The change instruction is created when the information processing device that receives information from the communication device determines the necessity of changing the information acquisition timing based on the received information and determines that the change is necessary. It may be information.

The change instruction is created by determining whether or not it is necessary to increase the frequency of information acquisition based on learning processing for detecting signs of deterioration or abnormality of the power storage element or power supply-related device based on information transmitted from the communication device. It may be the one that has been done. In this case, when the instruction unit determines that it is necessary to increase the frequency, the instruction unit determines the acquisition timing after the change and creates an instruction for the change. With this configuration, it is possible for the information processing device to autonomously detect a sign, and if necessary, frequently acquire information to accurately determine an abnormality. As the learning process, various processes such as statistical analysis, regression analysis, and deep learning can be used.

The information processing device collectively collects information including the state of the power storage element or the power supply-related device for each system including the power storage element or the power supply-related device, or for each place where the power storage element or the power supply-related device is installed. The transmission processing unit may be provided to transmit the display information to be displayed to the requester of the information including the above state. The display information may include connection information to the communication device that provides screen information for displaying a screen that accepts the timing change.

With the above configuration, connection information to the communication device can be acquired via the information processing device. A client device having a display unit can display a screen for accepting a change in information acquisition timing based on the connection information. It is possible to change the timing of information acquisition remotely.

The information processing system processes information by a communication device connected to a power storage element or a power supply-related device and an information processing device that transmits and receives information between the communication devices. In the information processing system, the communication device transmits information including the state of the power storage element or the power supply-related device acquired at a timing based on the setting to the information processing device, and the information processing device changes the timing. Judge the necessity. When the information processing device determines that the change is necessary, the information processing device transmits an instruction for changing the timing to the communication device, and the communication device changes the timing based on the received instruction for the change.

The computer program causes a computer provided with a display unit to receive and display information on a power storage element and / or a power supply-related device. In the computer program, display information for displaying the status of the power storage element and / or the power supply-related device is provided on the computer for each system including the power storage element or the power supply-related device, or the power storage element or the power supply-related device is installed. A step to request for each location, a step to collectively display for each system or location based on the display information transmitted in response to the request, the power storage element or power supply related to the display information. The step of communicating with the communication device based on the connection information to the communication device connected to the device, and the timing of acquiring the information including the state in the power storage element or the power supply related device provided from the communication device. Execute the step to display the screen for accepting changes.

The present invention will be specifically described with reference to the drawings showing the embodiments thereof.

FIG. 1 is a diagram showing an outline of the remote monitoring system 100. The remote monitoring system 100 enables remote access to information on power storage elements and power supply related devices included in the mega solar power generation system S, the thermal power generation system F, and the wind power generation system W. An uninterruptible power supply (UPS) U and a rectifier (DC power supply or AC power supply) D installed in a regulated power supply system for railways are also remotely monitored. The power storage element and the power supply-related device are not limited to industrial use, but may be for home use.

A power conditioner (PCS: Power Conditioning System) P and a power storage system 101 are arranged side by side in the mega solar power generation system S, the thermal power generation system F, and the wind power generation system W. The power storage system 101 is configured by arranging a plurality of containers C accommodating the power storage module group L in parallel. The power storage module group L includes a plurality of power storage elements. The power storage element is preferably a rechargeable battery such as a lead storage battery or a lithium ion battery or a capacitor. A part of the power storage element may be a primary battery that cannot be recharged.

In the remote monitoring system 100, the communication device 1 is mounted / connected to each of the power storage system 101 or the device (P, U, D and the management device M described later) in the systems S, F, W to be monitored (P, U, D and the management device M described later). See Figure 2). The remote monitoring system 100 is between a communication device 1, a server device 2 (information processing device) that collects information from the communication device 1, a client device 3 (communication terminal device) for viewing the collected information, and the device. Includes network N, which is a communication medium of the above.

The communication device 1 may be a terminal device (measurement monitor) that communicates with a battery management device (BMU: Battery Management Unit) provided in the power storage element and receives information on the power storage element, or may be an ECHONET / ECHONET Lite (registered trademark). ) It may be a compatible controller. The communication device 1 may be a network card type device that can be mounted on the power conditioner P or the power storage module group L. One communication device 1 is provided for each group including a plurality of power storage modules in order to acquire information on the power storage module group L in the power storage system 101. A plurality of power conditioners P are connected to enable serial communication, and the communication device 1 is connected to a control unit of one of the representative power conditioners P.

The server device 2 includes a Web server function, and presents information obtained from the communication device 1 mounted / connected to each device to be monitored according to the access from the client device 3. The communication device 1 also includes a Web server function, and has a Web-based interface for setting the communication device 1 in response to access from a client device. The interface on which the server device 2 presents information includes a link (connection information) to the interface of the communication device 1, and the client device 3 directly communicates with the communication device 1 to connect to the communication device 1 remotely. Operation is possible.

The network N includes a public communication network N1 which is a so-called Internet and a carrier network N2 which realizes wireless communication according to a predetermined mobile communication standard. The public communication network N1 includes a general optical line, and the network N includes a dedicated line to which the server device 2 is connected. The network N may include an ECHONET / ECHONET Lite compatible network. The carrier network N2 includes a base station BS, and the client device 3 can communicate with the server device 2 from the base station BS via the network N. An access point AP is connected to the public communication network N1, and the client device 3 can send and receive information from the access point AP to and from the server device 2 via the network N.

In this way, the remote monitoring system 100 uses the communication device 1 mounted or connected to each device to be monitored, and is detected by the state and device of the power storage element such as SOC and SOH (State Of Health) in the power storage system 101. The server device 2 collects information such as an abnormality. The collected information is collectively presented via the server device 2.

As shown in FIG. 2, the communication device 1 includes a control unit 10, a storage unit 11, a first communication unit 12, and a second communication unit 13. The control unit 10 is a processor using a CPU (Central Processing Unit), and uses a built-in memory such as a ROM (Read Only Memory) and a RAM (Random Access Memory) to control each component to execute processing.

The storage unit 11 uses a non-volatile memory such as a flash memory. The storage unit 11 stores the device program 1P read and executed by the control unit 10. The device program 1P includes an embedded OS (Operating System) using Linux (registered trademark), a Web server running on the OS, SSH (Secure Shell), SNMP (Simple Network Management Protocol), etc. for communication. Contains the program. The device program 1P stored in the storage unit 11 may be a device program 4P stored in the recording medium 4 read out and duplicated in the storage unit 11. The device program 1P may include a mailer program, and when an abnormality occurs, an e-mail may be automatically sent to a preset e-mail address. These programs may be stored in the memory (ROM) built in the control unit 10. The storage unit 11 stores the sampling timing settings related to the collection of information. The sampling timing is a sampling cycle such as 1 minute and 1 second. The sampling timing is not limited to a fixed period, and may be a specific pattern or may be based on an event (change in measured values such as temperature, voltage, and current). The storage unit 11 stores information such as information collected by the processing of the control unit 10 and an event log. The information stored in the storage unit 11 can also be read out via a communication interface such as USB whose terminals are exposed in the housing of the communication device 1.

The first communication unit 12 is a communication interface that realizes communication with a monitored device to which the communication device 1 is connected. The first communication unit 12 uses, for example, a serial communication interface such as RS-232C or RS-485. For example, the power conditioner P includes a control unit having a serial communication function compliant with RS-485, and the first communication unit 12 communicates with the control unit. When the control board provided in the power storage module group L or the management device (FIG. 3) for controlling the power storage module is connected by a CAN (Controller Area Network) bus and communicates with each other by CAN communication, the first communication unit 12 It may be a communication interface based on the CAN protocol. The first communication unit 12 may be a communication interface that performs communication based on the ECHONET / ECHONET Lite standard.

The second communication unit 13 is an interface that realizes communication via the network N, and uses, for example, a communication interface such as Ethernet (registered trademark) or a wireless communication antenna. A communication interface for communication based on the ECHONET / ECHONET Lite standard may be used. The control unit 10 can communicate with the server device 2 or the client device 3 via the network N by the second communication unit 13.

In the communication device 1 configured in this way, the control unit 10 acquires various information including the state information of the monitored device to which the communication device 1 is connected via the first communication unit 12. By reading and executing the Web server program, the control unit 10 can receive a communication connection from the server device 2 or the client device 3 as a Web server and present information. The control unit 10 can receive an operation instruction remotely by SSH. The control unit 10 receives, for example, instructions for changing the sampling timing for status acquisition and shutting down. The control unit 10 functions as an SNMP agent by reading and executing the SNMP program, and can also respond to an information request from the server device 2.

The server device 2 uses a server computer and includes a control unit 20, a storage unit 21, and a communication unit 22. In the present embodiment, the server device 2 will be described as one server computer, but the processing may be distributed among a plurality of server computers.

The control unit 20 is a processor using a CPU or a GPU (Graphics Processing Unit), and uses a built-in memory such as a ROM and a RAM to control each component and execute processing. The control unit 20 executes information processing based on the server program 2P stored in the storage unit 21. The server program 2P includes a Web server program, and the control unit 20 functions as a Web server that provides a Web page to the client device 3 and accepts a login to a Web service. The control unit 20 can also collect information from the communication device 1 as an SNMP server based on the server program 2P.

The storage unit 21 uses a non-volatile memory such as a hard disk or a flash memory. In addition to storing the server program 2P described above, the storage unit 21 stores data including the states of the power conditioner P and the power storage module group L of the power storage system 101 to be monitored collected by the processing of the control unit 20. Remember. The server program 2P may be one that reads out the server program 5P stored in the recording medium 5 and duplicates it in the storage unit 21.

The communication unit 22 is a communication device that realizes a communication connection and data transmission / reception via the network N. Specifically, the communication unit 22 is a network card corresponding to the network N.

The client device 3 is a computer used by an operator such as an administrator or a maintenance person of the power storage system 101 of the power generation systems S, F, and W. The client device 3 may be a desktop type or laptop type personal computer, or may be a so-called smartphone or tablet type communication terminal. The client device 3 includes a control unit 30, a storage unit 31, a communication unit 32, a display unit 33, and an operation unit 34.

The control unit 30 is a processor using a CPU. The control unit 30 causes the display unit 33 to display the Web page provided by the server device 2 or the communication device 1 based on the client program 3P including the Web browser stored in the storage unit 31.

The storage unit 31 uses a non-volatile memory such as a hard disk or a flash memory. Various programs including the client program 3P including the Web browser are stored in the storage unit 31. The client program 3P may be one that reads out the client program 6P stored in the recording medium 6 and duplicates it in the storage unit 11.

The communication unit 32 uses a communication device such as a network card for wired communication, a wireless communication device for mobile communication connected to the base station BS (see FIG. 1), or a wireless communication device corresponding to connection to the access point AP. .. The control unit 30 can make a communication connection or send / receive information to / from the server device 2 or the communication device 1 via the network N by the communication unit 32.

The display unit 33 uses a display such as a liquid crystal display or an organic EL (Electro Luminescence) display. The display unit 33 displays an image of a Web page provided by the server device 2 by processing based on the client program 3P of the control unit 30. The display unit 33 is preferably a touch panel built-in display, but may be a touch panel non-built-in display.

The operation unit 34 is a user interface such as a keyboard and a pointing device capable of input / output from the control unit 30, or a voice input unit. The operation unit 34 may use the touch panel of the display unit 33 or the physical buttons provided on the housing. The operation unit 34 notifies the control unit 20 of the operation information by the user.

The remote monitoring system 100 configured in this way is a server device 2, and includes various states including a power conditioner P, a power storage module group L (a management device M described later), an uninterruptible power supply U, and a rectifier D. Information is acquired from the communication device 1 periodically or in response to a request from the client device 3 and stored in the storage unit 21. The storage unit 21 stores the information that identifies the device (P, M, U, D) from which the information is acquired and the acquired time information in association with each other. The server device 2 processes the latest data and its history stored in the storage unit 21 so that the client device 3 can acquire or acquire (download) the latest data as data on a Web page. The server device 2 can comprehensively present the information acquired from the power storage element or each power supply-related device using the communication device 1 to the client device 3.

The power storage module group L has a hierarchical structure. FIG. 3 is a diagram showing an example of the hierarchical structure of the power storage module group L and the connection form of the communication device 1. The power storage module group L includes, for example, a power storage module (also referred to as a module) in which a plurality of power storage cells (also referred to as cells) are connected in series, a bank in which a plurality of power storage modules are connected in series, and a domain in which a plurality of banks are connected in parallel. It is composed of a hierarchical structure. In the example of FIG. 3, a management device M is provided for each of the banks numbered (#) 1-N and for each domain in which the banks are connected in parallel. The management device M provided for each bank communicates with a control board (CMU: Cell Monitoring Unit) having a communication function built in each of the power storage modules by serial communication, and states the power storage module and the cells inside. It executes management processes such as acquisition of (current, voltage, temperature), balance adjustment for each bank according to each state, and detection of abnormal communication status. Communication connection between the plurality of management devices M is possible by CAN communication, LAN, ECHONET Lite, or serial communication. The bank management device M transmits information on the power storage module of each bank to the management device M provided for each domain. The domain management device M aggregates the information obtained from the management device M of the bank belonging to the domain.

In the example of FIG. 3, the communication device 1 is connected to the management device M for each domain and the management device M for each bank via a communication line or a signal line. The communication device 1 connected to each management device M is communication-connected so as to transmit and receive information to and from each other. In the example shown in FIG. 3, they are connected by a communication bus. The communication bus may be a CAN bus or a LAN cable. The communication device 1 connected to the domain management device M may communicate with another communication device 1 connected to the management device M of another domain in the same system.

FIG. 4 is a diagram showing another example of the hierarchical structure of the power storage module group L and the connection form of the communication device 1. In the example of FIG. 4, the power storage module group L is composed of only one bank in which a plurality of power storage modules are connected in series (standalone). In the example of FIG. 4, the communication device 1 is connected only to the management device M for each bank, and does not communicate with other communication devices 1.

As shown in FIG. 2, the control unit 10 of the communication device 1 may receive an instruction to determine the operation of the connected power storage element or power supply-related device based on the device program 1P stored in the storage unit 11. It is possible. The content of the instruction is, for example, determination or change of sampling timing for state acquisition. FIG. 5 is a flowchart showing an example of the instruction receiving procedure in the communication device 1. The control unit 10 of the communication device 1 starts the following processing each time the second communication unit 13 detects a communication event from the server device 2 or the client device 3.

The control unit 10 determines whether or not the communication event is a request for transmission of information including the state of the power storage element or the power supply-related device from the server device 2 (step S101). When it is determined that the request is a transmission (S101: YES), the control unit 10 acquires the latest information from the connected device by the first communication unit 12, or acquires it at a sampling timing set in advance. Then, the stored information is read out and acquired (corresponding to step S102, "acquisition unit"). The control unit 10 transmits information including the acquired state from the second communication unit 13 to the server device 2 (corresponding to step S103, “transmission unit”), and ends the process. Even if the control unit 10 transmits the information acquired by the first communication unit 12 according to a preset schedule (10 minutes, 30 minutes, every hour, etc.) without receiving the transmission request in step S101. Good. The control unit 10 may transmit information when the amount of information (number or data size) of the stored information reaches a preset upper limit.

When it is determined in step S101 that the communication event is not a transmission request (S101: NO), the control unit 10 determines whether or not the communication event is a connection request request from the client device 3 (step S104). .. The connection request is transmitted when requesting to browse the Web page presented by the communication device 1. When it is determined that the request is a connection request (S104: YES), the control unit 10 acquires the latest information including the status information from the connected device by the first communication unit 12 (step S105). The control unit 10 creates a Web page including the latest acquired information (updates the data included in the Web page) (step S106), and requests the display information for displaying the created Web page from the client device 3 Is transmitted from the second communication unit 13 to (step S107).

The control unit 10 accepts an operation on the Web page displayed on the display unit 33 of the client device 3 (step S108). It is determined whether or not the sampling timing change screen is selected by the operation in step S108 (step S109).

When it is determined that the sampling timing change screen is selected (S109: YES), the control unit 10 accepts the sampling timing change on this change screen (step S110, corresponding to the “change reception unit”). The control unit 10 stores the received sampling timing change (sampling timing after the change) in the storage unit 11 (step S111), and proceeds to the process in step S112. The control unit 10 may accept the sampling cycle and the period during which the setting is valid as the sampling timing after the change. After the storage process of S111, the control unit 10 acquires information from the connected devices (P, M, U, D) based on the stored changed sampling timing. The default sampling timing is separately stored in the storage unit 11 and can be referred to by the control unit 10.

If it is determined that the operation is other than the selection of the sampling timing setting screen (S109: NO), the Web page is updated according to each operation (step S113), and the process proceeds to step S112.

The control unit 10 determines whether or not the logout or the end operation of the Web browser has been performed by the operation of the operation unit 34 in the client device 3 (step S112), and when it is determined that the logout or the end operation has been performed (step S112). S112: YES), the process is terminated. When it is determined that the log-out or end operation has not been performed (S112: NO), the control unit 10 returns the process to step S108 and continues accepting the operation.

If it is determined in step S104 that it is not a connection request request (S104: NO), the communication event is the transmission of instruction information, and the control unit 10 receives this (step S114). The control unit 10 stores the received instruction information in the storage unit 11 (step S115), operates based on the stored instruction information, and ends the process. The instruction information may be an instruction to change the sampling timing, or may be information instructing the operation of the communication device 1 itself or the operation of the connected device (P, M, U, D). .. The instruction information may be, for example, a command group.

The screen example displayed on the display unit 33 of the client device 3 will be described with respect to the processing procedure shown in the flowchart of FIG. 6 and 7 are diagrams showing screen examples presented by the server device 2, and FIGS. 8 and 9 are diagrams showing screen examples presented by the communication device 1.

The screen example of FIG. 6 shows a case where the user (operator) uses the client device 3 to use the remote monitoring system 100, logs in via the login screen provided from the Web server of the server device 2, and successfully logs in. Is displayed in. The client device 3 causes the display unit 33 to display a Web screen 330 including a list of system or device names extracted from the login information based on the screen information transmitted from the server device 2. In the example of FIG. 6, the names such as "XY city mega solar system" of the mega solar power generation system S and "WZ power plant system" of the thermal power plant system F shown in FIG. 1 are given together with the identification information (identification number). It is displayed as a link.

The Web screen 330 provided by the server device 2 includes menus 331 such as "system search", "life prediction", "download", and "report". Menu 331 includes "new registration" and "edit". The Web screen 330 includes a button 332 for a log-out or end operation.

FIG. 7 is a diagram showing an example of a screen in which information is collectively displayed for each system. FIG. 7 is the Web screen 330 displayed in FIG. 6, which is displayed on the display unit 33 when the “XY city mega solar system” is selected by the operation of the operation unit 34 of the client device 3. In the screen example of FIG. 7, a name that identifies each of the power storage module groups L composed of a plurality of domains including a plurality of banks according to the system configuration of the power storage system 101 used by the "XY city mega solar system" ( Or the icon 333 including the identification number) is displayed. Regarding the power storage module group L, there are an "+/-" icon 334 for expanding or folding the hierarchical structure, an icon 335 for displaying detailed information of each, and an icon 336 for displaying detailed information (real time). Is placed. The icon 336 is arranged together with the identification information (device ID) of the communication device 1 connected to the power storage module group L.

As shown in FIG. 3, the power storage system 101 of the "XY city mega solar system" has a plurality of banks in which a plurality of modules including n cells (n is a natural number; 12 in the present embodiment) are connected in series. It has a power storage module group L having a plurality of domains held in parallel. As shown in FIG. 7, when the “+/-” icon 334 corresponding to the domain is selected on the Web screen 330, the list corresponding to the bank belonging to the domain is expanded. When the "+/-" icon 334 corresponding to the bank in the expanded list is selected, the list of power storage modules belonging to the bank is expanded. Each power storage module contains n cells, and when the "+/-" icon 334 corresponding to the power storage module is selected on the screen 330 by the operation of the operation unit 34 of the client device 3, the power storage module is included in the power storage module. The list of cells (image) is expanded as shown in FIG. In FIG. 7, the icon 336 for acquiring the detailed information is arranged in each layer corresponding to the management device M on which the communication device 1 is mounted / connected, that is, in both the domain and the bank.

FIG. 8 is a diagram showing a display example of detailed information. FIG. 8 is presented by the Web server of the communication device 1 based on the link information associated with the icon 336 when the icon 336 of the hierarchy corresponding to the domain of the power storage module group L of FIG. 7 is selected. This is an example of the Web screen 337. Login is required to display the Web screen 337 provided by the communication device 1 shown in FIG. The login information at this time is common to the login to the Web server provided by the server device 2, and it is preferable that the login information is automatically logged in and displayed without performing the operation of inputting the login information again.

Information obtained from the control board mounted on each power storage module via the management device M provided in the domain hierarchy or the management device M provided in each bank on the Web screen 337. Is provided to the client device 3. Specifically, on the Web screen 337, "domain information" includes the domain status (normal / abnormal), the number of banks included in the domain (total number of banks), and the number of banks operating in all banks (operating). The number of banks), the total voltage of the domain, the current, the cell voltage, the SOC, and the temperature distribution (highest, mean, and lowest) are included. The "data date and time" is also displayed on the Web screen 337.

The Web screen 337 presented by the communication device 1 includes a plurality of menu icons 338. The plurality of menu icons 338 include, for example, a menu for displaying detailed information of "domain information" obtained via the communication device 1. The menu icon 338 is for setting the time in the communication device 1, the setting of the e-mail address for notification about maintenance, the network setting, the setting related to SNMP, the setting related to the control via serial communication, or the restart (shutdown) of the communication device 1. Includes menu. The menu icon 338 includes a menu for manually changing the sampling timing shown in the flowchart of FIG.

The communication device 1 updates the information in the presented Web screen 337 according to the content update of the "domain information". The communication device 1 transitions the Web screen 337 by selecting and operating these menu icons 338 on the operation unit 34 of the client device 3.

FIG. 9 is a diagram showing another example of the Web screen 337 presented from the communication device 1. FIG. 9 is an example of a screen displayed when an icon for changing the sampling timing is selected from the menu icons 338 of FIG. The client device 3 capable of displaying the screen example of FIG. 9 may be limited to the one in which the user (operator) to which the administrator authority is assigned is logged in. As shown in FIG. 9, when the menu icon 338 is selected, a screen 339 that is superimposed on the Web screen 337 is displayed, and an icon 340 for returning to the Web screen 337 of FIG. 8 is displayed. On the screen 339, the identification number of the domain corresponding to the communication device 1 and the state information (total number of banks included) are displayed.

The screen 339 includes a setting screen 341 for changing the sampling timing of the state information in the domain to which the communication device 1 of the presentation source of the Web screen 337 is connected. The example of the setting screen 341 shown in FIG. 9 includes an input field for a sampling timing cycle, a selection field for a valid period of the sampling timing to be changed, and an input field for the valid period. In the example shown on the screen 339, as shown in FIG. 3, since a plurality of banks are included in the lower layer of the domain, the setting including the sampling timing input field, the valid period selection field, and the input field for each corresponding bank. Screen 342 is included. The screen 339 includes a change button 343. When the change button 343 is selected by the operation unit 34 after the selection or input is performed on both or one of the domain setting screen 341 and the bank setting screen 342, the change is accepted (S110) and stored. (S111). In this way, it is possible to manually receive a change in sampling timing by the communication device 1 remotely via the Web screen 337 presented by the communication device 1.

The Web screen 337 shown in FIG. 9 is presented from the communication device 1 mounted / connected to the management device M provided in the hierarchy of the domain having a plurality of banks in the lower layer. As described above, in the Web screen 337 shown in FIG. 9, it is possible to change the sampling timing of the lower layer bank including the bank setting screen 342. With this configuration, even if the bank is also provided with the communication device 1, the sampling timing in the lower layer can be changed in the communication device 1 in the higher layer, and the operability is improved. Even if a plurality of banks are held in the lower layer, the bank setting screen 342 may be disabled on the Web screen 337 presented from the communication device 1 in the domain layer. In this case, the change of the sampling timing of the lower layer bank is accepted on the Web screen presented from the communication device 1 mounted / connected to the management device M provided in the bank layer. On this Web screen, only the sampling timing setting screen 342 of the corresponding bank (for example, only the bank of "# 1") is displayed.

A case may be considered in which sampling timings are collectively set for a plurality of parallel domains in the same power storage system 101. In this case, in the Web screen 330 shown in FIG. 7 presented by the server device 2, a button for accepting a change in sampling timing may be provided in, for example, in the menu 331.

As shown in FIG. 9, it is possible to change different sampling times for the domain and the bank, and it is also possible to set a period during which the changed sampling time is valid.

In this way, the communication device 1 can remotely accept a change in sampling timing for acquiring the state of the power storage element or the power supply-related device in the mounted / connected device. It is also possible for the remote monitoring system 100 to automatically change the sampling timing by utilizing the fact that it can be received remotely. The automatic change will be described below.

As a case where it is necessary to change the sampling timing from the initial setting, there is a case where it is necessary to acquire the state in detail for a part or all of the power storage module group L, and conversely, the frequency of acquiring the state in detail is reduced. It is considered that the case is determined to be acceptable. In the former case, when a sign of abnormality in a part or all of the power storage module group L is detected based on the state information acquired from each power storage module and collected by the server device 2, or the power storage element This is the case of calculating the deterioration rate (life). The latter case is a case where the efficiency of processing such as life prediction using the collected and accumulated state information is improved, and the processing can be performed while maintaining the accuracy without acquiring the state information frequently. Is. When the sampling frequency is high, the processing load becomes heavy, and the amount of information including the state transmitted from the communication device 1 to the server device 2 at a timing independent of the sampling frequency becomes large and the communication load becomes heavy. .. Therefore, considering the processing load and communication load, it is preferable that the sampling frequency is low if the accuracy can be maintained. It is desirable that the sampling frequency can be optimized.

FIG. 10 is a flowchart showing an example of a processing procedure in the server device 2. The control unit 20 of the server device 2 periodically executes the following processing procedure.

The control unit 20 selects one system or device to be monitored (step S201). In step S201, the control unit 20 selects one from the identification information of the system or device to be monitored stored in the storage unit 21. For the selected system or device, the control unit 20 determines whether or not a sign of abnormality has been detected based on the state information of the power storage module group L (corresponding to step S202, “determination unit”). The detection of the sign may be performed by statistical analysis based on the state information in the server device 2 or by threshold determination. The detection of the sign may be performed based on the artificial intelligence determination by learning about the deterioration or abnormality prediction based on each acquired state information. The artificial intelligence determination is, for example, deep learning in which state information is used as an input layer and the state is output as a determination result. Other determinations may be by regression analysis on state information.

When it is determined that a sign of abnormality has been detected (S202: YES), the control unit 20 determines the changed sampling timing so as to increase the sampling frequency (step S203). The control unit 20 creates instruction information for instructing the change that describes the determined sampling timing after the change (step S204), and transmits the created instruction information to the communication device 1 corresponding to the selected system or device. (Step S205, corresponding to the "indicator"). The control unit 20 determines whether or not all the systems or devices have been selected (step S206), and if it is determined that they have not been selected (S206: NO), returns the process to step S201 and determines that the selection has been made. If (S206: YES), the process ends.

The process of step S205 corresponds to steps S114 and S115 in the process procedure executed by the communication device 1 shown in the flowchart of FIG. When the instruction information instructing the change of the sampling timing is transmitted from the server device 2 as described above, the control unit 10 of the communication device 1 receives this (S114) and stores the change included in the instruction information (S114). S115).

If it is not determined that a sign of abnormality has been detected (S202: NO), the control unit 20 determines whether or not there has been a trigger input for changing the sampling timing (corresponding to step S207, “determination unit”). The trigger may be output by the control unit 20 itself based on the schedule stored in the storage unit 21 in association with the selected system or device, the peripheral environment of the system, the status of other devices, etc. It may be output based on the situation determination by the external device based on. The trigger may be an instruction from the client device 3 and may be output by a menu included in the Web screen 330 of FIG.

When it is determined in step S207 that the trigger input has been made (S207: YES), the control unit 20 determines the changed sampling timing based on the conditions specified corresponding to the trigger input (step S208). The control unit 20 creates and transmits instruction information instructing the timing change (S204, S205).

When it is determined in step S207 that there is no trigger input (S207: NO), the control unit 20 determines whether or not a stable state has been detected for the selected system or device based on the state information of the power storage module group L. (Step S209, corresponding to "judgment unit").

When it is determined that the stable state has been detected (S209: YES), the control unit 20 determines the sampling timing after the change so as to reduce the sampling frequency (step S210). The control unit 20 creates and transmits instruction information instructing the timing change (S204, S205), and ends the process.

If it is determined that the stable state is not detected (S209: NO), the control unit 20 advances the process to step S206.

The processing procedure shown in the flowchart of FIG. 10 is merely an example. It is preferable that the sampling timing can be changed according to various conditions so that the sampling frequency is optimized for the entire remote monitoring system 100 in consideration of the processing load of each communication device 1 and the communication load in the network N.

Conventionally, in the management device M that manages the power storage module group L, the sampling timing for acquiring the state of the power storage element is based on the initial setting, and in order to change it, go to the site where the management device M is installed. The person in charge of maintenance went to do it. By using the power storage module group L and the remote monitoring system 100 capable of remotely monitoring the state of the entire system including the power storage module group L, sampling timing can be set via the communication device 1 in response to an operation by the operation unit 34 in the client device 3. Can be changed. Therefore, it is possible to reduce the burden on the maintenance staff and reduce the cost required for maintenance management.

The embodiments disclosed as described above are exemplary in all respects and are not restrictive. The scope of the present invention is indicated by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

1 Communication device 10 Control unit 11 Storage unit 1P device program 2 Server device 20 Control unit 21 Storage unit 2P server program 3 Client device 30 Control unit 31 Storage unit 3P client program

Claims (9)

Storage element or a power conditioner, uninterruptible power supply, or connected to the power-related device is a rectifier, a first communication unit that communicates with the accumulating element or the power-related device,
An acquisition unit for acquiring, based on the electricity storage element or the timing condition set information including a power-related device,
The change reception unit that accepts and changes the timing change,
It is provided with a transmission unit that transmits information acquired by the acquisition unit at the timing after the change to the information processing device by a second communication unit capable of communicating with the information processing device.
The change receiving unit transmits screen information for displaying a screen for accepting the timing change to a client device including the display unit by the second communication unit without going through the information processing device, and the client device causes the client device. A communication device that accepts a change in timing on the screen displayed by a display unit provided. The change receiving section receives the second communication unit an indication of change in the timing sent from the previous SL information processing apparatus, a communication device according to claim 1. An information processing system that includes a communication device connected to a power storage element or a power conditioner, an uninterruptible power supply, or a power supply-related device that is a rectifier , and an information processing device that transmits and receives information between the communication devices. There,
The communication device is
An acquisition unit that acquires the electric storage element or the power-related device information including the state of power storage element or the power-related device by the first communication unit for communicating based on the set timing and,
The change reception unit that accepts and changes the timing change,
It is provided with a transmission unit that transmits information acquired by the acquisition unit at the timing after the change to the information processing device by a second communication unit capable of communicating with the information processing device.
The change receiving unit transmits screen information for displaying a screen for accepting the timing change to a client device including the display unit by the second communication unit without going through the information processing device, and the client device causes the client device. An information processing system that accepts changes in the timing on the screen displayed by the display unit provided. The information processing device includes a determination unit that determines whether or not the timing needs to be changed, and a determination unit.
The information processing system according to claim 3, further comprising an instruction unit that transmits an instruction for changing the timing to the communication device when the determination unit determines that the change is necessary. The determination unit determines whether or not it is necessary to increase the frequency of information acquisition based on learning processing for detecting signs of deterioration or abnormality of the power storage element or power supply-related device based on information transmitted from the communication device.
The information processing system according to claim 4, wherein the instruction unit determines a timing after the change and creates an instruction for the change when it is determined that an increase in frequency is necessary. The information processing device
Display for collectively displaying information including the state of the power storage element or power supply-related device for each system including the power storage element or power supply-related device, or for each place where the power storage element or power supply-related device is installed. A transmission processing unit that transmits information to a requester of information including the above state is provided.
The information processing according to any one of claims 3 to 5 , wherein the display information includes connection information to the communication device that provides screen information for displaying a screen that accepts the timing change. system. Information is processed by a communication device connected to a power storage element or a power conditioner, an uninterruptible power supply, or a power supply-related device such as a rectifier , and an information processing device that transmits and receives information between the communication devices. It is an information processing method
The communication device is
The electricity storage device or information including a state of the power-related device is acquired at a timing based on the set transmit to the information processing apparatus,
The screen information for displaying the screen for accepting the timing change is transmitted to the client device including the display unit without going through the information processing device, and the screen information displayed by the display unit included in the client device is displayed. Accept timing changes,
Information processing method. The information processing device
Judging the necessity of changing the timing,
When it is determined that a change is necessary, an instruction to change the timing is transmitted to the communication device.
The information processing method according to claim 7 . A computer program that causes a computer equipped with a display unit to receive and display information on a power storage element and / or a power conditioner, an uninterruptible power supply, or a power supply-related device that is a rectifier.
On the computer
The display information for displaying the state of the storage element and / or the power-related device, the accumulating device and / or each system containing the power-related device, or the storage element and / or the power-related device is installed Steps required for information processing equipment for each location,
A step of collectively displaying each system or each location based on the display information transmitted from the information processing apparatus in response to a request.
To the communication device based on the connection information to the communication device connected to the electric storage element or the power-related devices are included in the display information, the step of communicating connected without the information processing apparatus as a client device and computer program for executing the step of displaying a screen for accepting change timing for acquiring information including the state of the electric storage element or the power-related device is provided from the communication device.

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